Memristor: Difference between revisions

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In electrical circuit theory, the memristor is a passive circuit element. It has been described as the fourth basic type of passive circuit element, alongside the well-known capacitor, resistor, and inductor.^[1] The name is a portmanteau of memory resistor.

Although the memristor was predicted and described in 1971 by Leon Chua of UC Berkeley, in a paper in IEEE Transactions on Circuit Theory, ^[2] it was a hypothetical device for 37 years, with no known physical examples. In April 2008, a working memristor was announced by a team of researchers at HP Labs.^[3][4][5]

"The era of nanoscale electronics will be enabled by the memristor. This is not just an invention, it is a basic scientific discovery." —Leon Chua, April 2008^[6]

The new circuit element will enable the development of new class of high-density digital memory. Performance of memristors improves as they are scaled down, and they generate less heat than transistors. The memristor also has unique analog properties that may lead to the invention of other devices.^[6]

The memristor is an element in which the magnetic flux ${\displaystyle \Phi _{m}}$ is a function of the accumulated electric charge q in the device. The rate of change of flux with charge

${\displaystyle M(q)={\frac {\mathrm {d} \Phi _{m}}{\mathrm {d} q}}}$

is known as memristance. This is comparable to the other three fundamental circuit elements:

• Resistance: ${\displaystyle R(I)={\frac {\mathrm {d} V}{\mathrm {d} I}}}$
• Inductance: ${\displaystyle L(I)={\frac {\mathrm {d} \Phi _{m}}{\mathrm {d} I}}}$
• Capacitance: ${\displaystyle {\frac {1}{C(q)}}={\frac {\mathrm {d} V}{\mathrm {d} q}}}$

Here ${\displaystyle q}$ is electrical charge, ${\displaystyle I}$ is electrical current, ${\displaystyle V}$ is electrical potential and ${\displaystyle \Phi _{m}}$ is magnetic flux.

Applying Faraday's Law of Induction and the chain rule to the equation defining the memristance, one obtains that the voltage V across a memristor is related to the current I by the instantaneous value of the memristance:

${\displaystyle V(t)=M(q(t))I(t)\,}$

Thus at any given instant, a memristor behaves like an ordinary resistor. However, its "resistance" M(q) is a value which depends on the charge accumulated in the device. This differs from ordinary resistors where the resistance is determined by fixed physical properties and transistors where the resistance is controlled by either the voltage at or current through a gate electrode. A linear memristor (one for which M is constant) would thus be indistinguishable from a linear resistor (one for which R is constant), with M = R. Memristance can be said to depend on the history of the current that has flowed through the device the same way the voltage of capacitors does.

The memristor was used for characterizing the behavior of electrochemical cells.^[7]

Interest in the memristor revived in 2007 when an experimental solid-state version was reported^[8][9] by Stanley Williams^[10] of Hewlett Packard. A solid-state device could not be constructed until the unusual behavior of nanoscale materials made it possible. The device does not use magnetic flux as the theoretical memristor suggested, nor stores charge as a capacitor does, but instead achieves a resistance dependent on the current history using a chemical mechanism.

Samsung has a pending U.S. patent application for a memristor similar to that described by Williams. Thus it is questionable whether Williams's group is the originator of this structure.^[11]

Williams's solid-state memristors can be combined into transistors, though much smaller.^{[dubious – discuss]} They can also be fashioned into non-volatile solid-state memory, which would allow greater data density than hard drives with access times potentially similar to DRAM, replacing both components.^[12] HP prototyped a crossbar latch memory using the devices that can fit 100 gigabit in a square centimeter.^[13] The highest-density Flash memories store 16 gigabit in the same area, for comparison. HP has reported that its version of the memristor is about 10 times slower than DRAM.^[14]

The devices' resistance would be read with alternating current so that they do not affect the stored value.^[15]

Some patents related to memristors appear to include applications in programmable logic,^[16] signal processing,^[17] neural networks,^[18] and control systems.^[19]

• BBC News - Electronics' 'missing link' found 01 May 2008
• Nature News - Found: the missing circuit element 30 Apr 2008
• Wired.com - Scientists Create First Memristor: Missing Fourth Electronic Circuit Element 30 Apr 2008
• EE Times - 'Missing link' memristor created: Rewrite the textbooks? 30 April 2008

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